Effect of Light Intensity, Wavelength and Illumination Protocol on Hydrogen Production in Photobioreactors

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dc.contributor.authorUyar, Basar
dc.contributor.authorYucel, Meral
dc.contributor.authorGunduz, Ufuk
dc.contributor.authorEroglu, Inci
dc.date.accessioned2020-03-26T18:30:41Z
dc.date.available2020-03-26T18:30:41Z
dc.date.issued2012
dc.departmentSelçuk Üniversitesien_US
dc.description.abstractPhotofermentative hydrogen production is a bioprocess in which photosynthetic purple nonsulfur bacteria grow heterotrophically on organic acids like acetic acid, lactic acid and butyric acid and produce hydrogen using light energy under anaerobic conditions. Two enzymes are specifically involved in hydrogen production, namely nitrogenase and hydrogenase. While nitrogenases produce hydrogen under nitrogen-limited conditions acting as ATP-dependent hydrogenase, hydrogenases have the ability for both production and consumption of molecular hydrogen depending on the type of hydrogenase and physiological conditions. Photofermentation process can be achieved in a wide variety of conditions such as in batch or continuous mode, upon artificial or solar illumination, utilizing various carbon and nitrogen sources including food industry wastewater and dark fermentation effluents. Panel and tubular photobioreactors are the most applicable bioreactor types since they ensure simple design, reasonable material and production costs and high light energy utilization. Physiological parameters such as pH, temperature, medium composition and light intensity control the yield and hydrogen productivity of the bacteria. Hydrogen productivity and yield can also be increased by using genetically modified bacterial strains or immobilization of bacteria. Genetic studies focus on development of mutant strains by disrupting the uptake hydrogenase genes, altering pigmentation and blocking alternative by-product biosynthesis. Techno-economic evaluations show that photofermentative hydrogen production process is very near to the commercialization stage, however demo scale experience is necessary to solve some problems such as low rate of hydrogen production and the cost associated with photobioreactor scale-up. Furthermore, recent studies are trying to integrate photofermentation to dark fermentation to have an enhanced hydrogen production yield. Finally, the whole process could end up with a fuel cell application where the produced hydrogen is stored for future uses.en_US
dc.identifier.citationUyar, B., Yucel, M., Gunduz, U., Eroglu, I., (2012). Effect of Light Intensity, Wavelength and Illumination Protocol on Hydrogen Production in Photobioreactors. International Journal of Hydrogen Energy. (32), 54-77. DOI: 10.2174/978160805224011201010054.
dc.identifier.endpage77en_US
dc.identifier.isbn978-1-60805-224-0; 978-1-60805-411-4
dc.identifier.scopusqualityN/Aen_US
dc.identifier.startpage54en_US
dc.identifier.urihttps://hdl.handle.net/20.500.12395/28117
dc.identifier.volume32
dc.identifier.wosWOS:000431815100006en_US
dc.identifier.wosqualityN/Aen_US
dc.indekslendigikaynakWeb of Scienceen_US
dc.indekslendigikaynakScopusen_US
dc.language.isoenen_US
dc.publisherBentham Science Publen_US
dc.relation.ispartofState Of The Art And Progress In Production Of Biohydrogenen_US
dc.relation.publicationcategoryKitap Bölümü - Uluslararasıen_US
dc.rightsinfo:eu-repo/semantics/openAccessen_US
dc.selcuk20240510_oaigen_US
dc.subjectPhotofermentationen_US
dc.subjectRhodobacter sphaeroidesen_US
dc.subjectBiological hydrogen productionen_US
dc.subjectPhotobioreactorsen_US
dc.titleEffect of Light Intensity, Wavelength and Illumination Protocol on Hydrogen Production in Photobioreactorsen_US
dc.typeBook Chapteren_US

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